JP2002341299A - Method and device for optical modulation and optical radio transmission system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To actualize an optical modulation system which generates no unnecessary wave and to provide an optical radio transmission system which eliminates the need for a band-pass filter. SOLUTION: This system has a 1st driver part which applies a 1st bias voltage to an electric signal of an intermediate frequency band, a 2nd driver part which applies a 2nd bias voltage to a local oscillation signal, a two-branch part which branches an input light signal into two, a 1st optical modulation part which modulates one of the light signals branched by the two-branch part with the electric signal outputted from the 1st driver part, and a 2nd optical modulation part which modulates the other light signal with the electric signal outputted from the 2nd driver part; and at least the 1st bias voltage and 2nd bias voltage are so set that the carrier components that the light signals modulated by the 1st and 2nd modulation parts have are inverted in phase.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a high-frequency optical transmitter for optically transmitting a high-frequency signal in a microwave or millimeter-wave band, and more particularly, to optically convert a modulated signal (hereinafter referred to as an IF signal) in an intermediate frequency band into a high-frequency radio signal. The present invention relates to an optical modulation method that performs frequency conversion and does not generate unnecessary waves near a high-frequency wireless signal frequency, an optical modulation device thereof, and a wireless transmission system.

[0002]

2. Description of the Related Art FIG. 7 shows a conventional configuration of an optical wireless transmission system for optically transmitting a high-frequency signal. 401 is a center station,
402 is a wireless base station, 410 is a light source for downlink, 710 is an intensity modulator, 420 is an optical fiber, 430 is a photoelectric converter for downlink, 720 is a frequency converter for downlink, 690 is a local signal source, and 730 is a filter. Reference numeral 450 denotes an antenna unit.

[0003] The operation of the conventional optical wireless transmission system will be described below. In the center station 401, the light output from the down light source 410 is input to the intensity modulator 710. The intensity modulation section 710 modulates the intensity of the optical signal based on the modulation signal (IF signal) of the intermediate frequency to be transmitted. The modulated optical signal is transmitted to the wireless base station 402 via the optical fiber 420. In the wireless base station 402, the transmitted optical signal is converted into an electric signal by an optical-to-electrical conversion unit 430 for downlink, and an IF signal is output. The downlink frequency converter 720 converts the frequency of the IF signal using the local oscillation signal output from the local oscillation signal source 690, and outputs a radio frequency modulation signal (RF signal). Since the downstream frequency converter 720 includes unnecessary wave components other than the desired RF signal, the filter 730 removes the unnecessary wave components. Further, the RF signal is amplified to an appropriate level by the downstream photoelectric conversion unit 430 or the downstream frequency conversion unit 720 (the downstream photoelectric conversion unit 4).
In the case of amplification at 30, amplification is performed in the state of an IF signal), the light is radiated from the antenna unit 450 into space, and information is transmitted to the wireless terminal. With the above configuration, a high-quality wireless signal can be transmitted due to the low loss property of the optical fiber.

[0004]

However, when a conventional optical wireless transmission system is used, unnecessary waves are generated when frequency conversion is performed in a wireless base station, so that a band filter corresponding to a wireless frequency band is required. There's a problem.

According to the present invention, an IF signal and a local oscillation signal are input using an optical modulator having a configuration in which optical modulators are connected in parallel, the IF signal is frequency-converted into an RF signal, and input to each waveguide. By adjusting conditions such as the phase of an electrical signal to be performed, an optical modulation system that does not generate unnecessary waves is realized, and an optical wireless transmission system that does not require a bandpass filter is provided.

[0006]

According to a first aspect of the present invention, there is provided an optical modulator for inputting an optical signal, modulating the input optical signal, and outputting the modulated optical signal, wherein the optical modulator includes an intermediate frequency band. A first driver unit for inputting the electric signal of the first frequency and applying a first bias voltage to the electric signal of the intermediate frequency band;
A second driver unit for inputting a local signal used for frequency-converting the electric signal into a radio frequency band and applying a second bias voltage to the local signal, and bifurcating the input optical signal A two-branch unit, a first optical modulation unit that modulates one optical signal that is bifurcated by the two-branch unit with an electrical signal output from the first driver unit, A second optical modulator that modulates the other optical signal with an electric signal output from the second driver, and at least a first bias voltage applied by the first driver. The second bias voltage applied by the second driver unit is set so that the phase of each carrier component of the optical signal modulated by the first and second modulation units is inverted. It is characterized by being performed.

According to a second aspect of the present invention, there is provided an optical modulator, wherein the first optical modulator comprises:
And the modulation performed in the second light modulator, respectively.
The frequency spectrum of the modulated optical signal has a carrier component and a one-sideband component, and the one-sideband component of the optical signal modulated by the first optical modulator is modulated by the second optical modulator. The SSB modulation is performed so that the one sideband component of the obtained optical signal is modulated upside down.

According to a third aspect of the present invention, there is provided an optical wireless transmission system, comprising: a downstream light source; a downstream optical modulator for modulating light output from the downstream light source; and the downstream optical modulator. An optical fiber for transmitting an optical signal output from the
An optical-to-electrical converter for converting an optical signal output from the optical fiber into an electric signal, wherein the downstream optical modulator is the optical modulator according to claim 1 or 2.

The invention according to claim 4 of the present application is an optical wireless transmission system, wherein in the optical wireless transmission system according to claim 3, the photoelectric converter converts an optical signal output from the optical fiber. A flat antenna for emitting an electric signal to a space as a wireless signal is further provided.

According to a fifth aspect of the present invention, there is provided an optical wireless transmission system, comprising: a downstream light source for outputting a downstream optical signal; and a downstream optical modulator for modulating light output from the downstream light source. An upstream light source that outputs an upstream optical signal, an optical multiplexing unit that multiplexes the downstream optical signal and the upstream optical signal modulated by the downstream optical modulator, and an optical multiplexing unit that is output from the optical multiplexing unit. An optical fiber for transmitting an optical signal, an optical separation unit for separating the optical signal output from the optical fiber into the downstream optical signal and the upstream optical signal, and a downstream output from the optical separation unit. A downstream optical-to-electrical conversion unit that converts an optical signal for use into an electrical signal; an electrical signal output from the downstream optical-to-electrical conversion unit to an antenna unit; and an electrical signal output from the antenna unit to an upstream optical signal. A circulator section for outputting to the modulator; Via a circulator section, emits an electric signal output from the downstream photoelectric conversion section to a space as a radio signal, receives an incoming radio signal, and outputs the signal to the circulator section, and the circulator section An upstream optical modulator that modulates an upstream optical signal by an electric signal output from the antenna unit via an optical fiber; an optical fiber that transmits the upstream optical signal; and an upstream light that is output from the optical fiber. The optical modulator according to claim 1, further comprising an upstream photoelectric conversion unit that converts a signal into an electric signal, and a local signal source that outputs the local signal, wherein the downstream optical modulator is the optical modulation device according to claim 1. It is characterized by the following.

According to a sixth aspect of the present invention, there is provided an optical wireless transmission system according to the fifth aspect, wherein the local oscillation signal output from the local oscillation signal source is branched into two. A branching unit, and a frequency conversion unit that receives one local oscillation signal output from the local oscillation signal branching unit and converts an electric signal output from the upstream optical-electrical conversion unit into an electric signal in an intermediate frequency band. A local oscillator signal output from the local oscillator signal branching unit is input to the downstream optical modulator.

According to a seventh aspect of the present invention, there is provided an optical modulation method for inputting an optical signal, modulating the input optical signal, and outputting the modulated optical signal, wherein the optical modulation method includes inputting an electric signal in an intermediate frequency band. A first driver step of applying a first bias voltage to the electric signal of the intermediate frequency band, and a local oscillation signal used to convert the frequency of the electric signal to a radio frequency band, and A second driver step of applying a second bias voltage, a two-branch step of branching the input optical signal into two, and two steps in the two-branch step.
A first optical modulation step of modulating one of the branched optical signals with an electric signal output from the first driver step; and a second optical driver for dividing the other optical signal into two by the two-branch step. And a second light modulation step of modulating with an electric signal output from the step, wherein at least a first bias voltage applied in the first driver step and a second bias voltage applied in the second driver section are applied. The second bias voltage is set such that the phases of the respective carrier components of the optical signals modulated in the first and second optical modulation steps are inverted.

According to an eighth aspect of the present invention, there is provided an optical modulation method, wherein the first optical modulation method comprises:
And the modulation performed in the second optical modulation step is such that the frequency spectrum of the modulated optical signal has a carrier component and a one-sideband component, and the optical signal modulated in the first optical modulation step is One sideband component and the second
The SSB modulation is performed in such a manner that the one sideband component of the optical signal modulated in the optical modulation step is positioned upside down.

[0014]

(Embodiment 1) FIG. 1 shows an example of a configuration of an optical modulator for realizing an optical modulation system according to Embodiment 1 of the present invention. 1 is an IF input terminal, 2 is a local oscillator input terminal, 1
00 is an optical modulator, 110 is a parallel optical modulator, 120-1,
2 is a 1st and 2nd branch part, 130-1-4 are 1st-4th
140-1, 2 are first and second optical modulators, 1 is an IF input terminal, 2 is a local oscillation input terminal, 21 to 2
Reference numeral 4 denotes first to fourth electrodes, 11 to 16 first to sixth optical waveguides, 31 an optical input terminal, and 32 an optical output terminal.

Hereinafter, the operation of the first embodiment of the present invention will be described. An IF signal and a local oscillation signal are input to the IF input terminal 1 and the local oscillation input terminal 2, respectively, and supplied to the first and second branching units 120-1 and 120-2. The first and second branching units 120-1 and 120-2 respectively branch the IF signal and the local oscillation signal such that the phases are orthogonal. The branched IF signal is input to the first and second driver units 130-1 and 130-2, and the branched local signal is input to the third and fourth driver units 130-3 and 130-4, respectively. It is adjusted and a bias voltage is applied.

Each signal to which the bias voltage is applied is the first signal.
In the first to fourth electrodes 21 to 24, the first to fourth optical waveguides 1
The refractive indices 1 to 14 are respectively changed to change the phase of the propagating light. As a result, the first and second optical modulators 1
In steps 40-1 and 40-2, intensity modulation by an IF signal and intensity modulation by a local oscillation signal are performed. Here, the phase of light is 1
Assuming that the voltage that changes by 80 ° is Vπ, each bias voltage value corresponds to two optical waveguides (optical waveguides 11 and 12 or 13 and 1) in the first or second optical modulator 140-1 or 140-2.
The difference between the bias voltage values in 4) is set to Vπ / 2. At this time, the first and second optical modulators 140-1 and 140-1, 2
Is optical SSB modulation without one side band. This situation is shown in FIGS. 2 (a) and 2 (b). FIG. 2 (a)
Indicates an optical spectrum in the fifth optical waveguide unit 15, and a single sideband is generated at a frequency separated from the optical carrier by the IF signal frequency (here, fIF) by optical SSB modulation. Similarly, FIG. 2B shows the sixth optical waveguide 1
6 shows an optical spectrum at 6. One-sideband occurs at a frequency that is separated from the optical carrier by a local signal frequency (here, fLO). However, the bias voltage is set so that the sideband of the IF signal and the sideband of the local oscillation signal are generated upside down with respect to the optical carrier. Furthermore, when the two optical signals are combined and output, the phase of the optical carrier is 18
Set to differ by 0 °. As a result, as shown in FIG. 2C, in the optical signal spectrum, the carrier component is canceled,
Only two sideband components whose frequency interval is (fIF + fLO) apart remain. Therefore, when this optical signal is subjected to electro-optical conversion, the beat component of the two sideband components is extracted as an electric signal, and as a result, the IF signal of the frequency fIF is frequency-converted into an RF signal of the frequency (fIF + fLO). Will be. Also, since almost no optical signal components other than the two sideband components are generated, almost no unnecessary wave components other than the desired RF signal component are generated in the electrical signal after the photoelectric conversion.

In this example, the SSB modulation method has been described as a modulation method in the first and second optical modulators 140-1 and 140-2.
The frequency conversion function can be realized even by using the SB modulation method.
FIG. 3 shows a state of an optical spectrum when the optical DSB modulation method is used. FIGS. 3A and 3B show spectra modulated by the IF signal and the local oscillation signal, and sidebands occur on both sides of the optical carrier. By combining these two optical signals such that the phases of the optical carriers are different from each other by 180 °, as shown in FIG. 3C, the carrier components of the optical signal spectrum are canceled out, and the frequency interval is (fIF + fLO). ), Two pairs of sideband components remain. Therefore, when this optical signal is subjected to electro-optical conversion, the beat component of the two sideband components is extracted as an electric signal, and as a result, the IF signal of the frequency fIF is frequency-converted into an RF signal of the frequency (fIF + fLO). Will be.

As described above, in the first embodiment, the IF signal and the local oscillation signal are input to the two optical modulators configured in parallel, and the optical modulation is performed so that the optical carriers of the two cancel each other. By setting the bias voltage to the above, it is possible to perform frequency conversion in which unnecessary waves other than the desired RF signal component hardly occur. As a result, there is no need for a bandpass filter for removing unnecessary waves that are required for electrical frequency conversion.

(Embodiment 2) FIG. 4 shows the configuration of an optical wireless transmission system according to Embodiment 2 of the present invention. 1 is an IF input terminal, 2 is a local oscillator input terminal, 401 is a center station, 402
Is a wireless base station, 410 is a light source for downlink, 100 is an optical modulator, 420 is an optical fiber, 430 is a photoelectric conversion unit for downlink, 440 is an amplifier for downlink, and 450 is an antenna unit. Note that the same numbers are assigned to the optical modulators that perform the same operations as those in the above-described embodiment, and description thereof will be omitted.

The operation of the second embodiment of the present invention will be described below. In the center station 401, the IF signal and the local oscillation signal are input to the IF input terminal 1 and the local oscillation input terminal 2, respectively, and supplied to the optical modulation unit 100. Light modulator 1
At 00, the optical signal output from the down light source 410 is
Modulation is performed by the IF signal and the local oscillation signal. The modulated optical signal is opto-electrically converted by the downstream opto-electric converter 430 in the radio base station 402 via the optical fiber 420, and
An F signal is output. The RF signal is supplied to the downstream amplification unit 440.
After being amplified by, the light is emitted from the antenna unit 450 to the space. As described in the first embodiment, since the optical modulation unit 100 performs frequency conversion without generating unnecessary waves, the radio signal output from the photoelectric conversion unit 430 for downlink contains almost unnecessary waves. Therefore, the light can be directly emitted from the antenna unit 450 to the space.

As described above, in the second embodiment, the optical modulation unit shown in the first embodiment is used, and a radio signal is supplied to a radio base station by optical transmission. It is possible to provide a small, high-quality wireless base station composed of only the units. As a result, the installation tolerance of a small wireless base station is increased, so that a flexible optical wireless transmission system can be realized.

(Embodiment 3) FIG. 5 shows the configuration of an optical wireless transmission system according to Embodiment 3 of the present invention. 401 is a center station, 402 is a wireless base station, 410 is a light source for downlink, 1
00 is an optical modulator, 510 is an optical amplifier, 420 is an optical fiber, and 520 is an antenna-integrated photoelectric converter. In addition,
The same numbers are assigned to those performing the same operations as those in the above-described embodiment, and the description thereof is omitted.

Hereinafter, the operation of the third embodiment of the present invention will be described. In the center station, the optical signal modulated by the optical modulator 100 is amplified by the optical amplifier 510, input to the optical fiber 420, and transmitted to the wireless base station 402. In the wireless base station 402, the antenna-integrated optical-electrical conversion unit 520 converts an optical signal into an electric signal, and simultaneously emits a radio signal from the antenna to space. As in Embodiment 2, the wireless signal output from the photoelectric conversion unit 430 contains almost no unnecessary wave, and thus can be directly emitted from the antenna unit 450 into space. As an example of the configuration of the antenna-integrated photoelectric converter 520, a photodiode that performs photoelectric conversion and a patch antenna that can be formed on a flat substrate are provided on the same substrate,
If the output from the photodiode is directly connected to the patch antenna to emit an electric signal to the space, the wireless base station 402 can be significantly reduced in size.

As described above, in the third embodiment, by using the optical modulation section shown in the first embodiment and amplifying in the state of an optical signal to supply the signal to the radio base station, unnecessary waves can be obtained. Is supplied, a high-level signal is supplied, so that the radio signal can be emitted from the antenna as it is after photoelectric conversion. The station can be significantly reduced in size.

(Embodiment 4) FIG. 6 shows the configuration of an optical wireless transmission system according to Embodiment 4 of the present invention. 401 is a center station, 402 is a wireless base station, 410 is a light source for downlink, 1
00 is an optical modulator, 620 is an optical multiplexer, 420 is an optical fiber, 630 is an optical separator, 430 is a downstream photoelectric converter,
440 is a downstream amplification unit, 640 is a circulator unit,
50 is an antenna unit, 650 is an upstream amplifying unit, 660 is an upstream optical modulation unit, 670 is an upstream photoelectric conversion unit, 680 is an upstream frequency conversion unit, and 690 is a local oscillation signal source. It is to be noted that the same operations as those in the above-described embodiment are assigned the same reference numerals, and description thereof will be omitted.

Hereinafter, the operation according to the fourth embodiment of the present invention will be described. In the center station 401, the downstream IF signal and the local oscillator signal are input to the IF input terminal 1 and the local oscillator input terminal 2, respectively, and supplied to the optical modulator 100. The optical modulator 100 modulates the downstream optical signal output from the downstream light source 410 with the downstream IF signal and the local oscillation signal.
The modulated downstream optical signal is multiplexed with the upstream optical signal output from the upstream light source 610 in the optical multiplexing unit 620, and then input to the optical fiber 420, and
Transmitted to In the wireless base station 402, the optical demultiplexing unit 630 demultiplexes the downstream optical signal and the upstream optical signal. The upstream optical signal is input to the upstream optical modulator 660. The downstream optical signal is converted into an electrical signal in the downstream optical-electrical conversion unit 430, amplified by the downstream amplification unit 440, and radiated from the antenna unit 450 to the space via the circulator unit 640.

On the other hand, the radio signal incident on the antenna section 450 is input to the upstream amplification section 650 via the circulator section 640, and is amplified and thereafter transmitted to the upstream optical modulation section 650.
In, the upstream optical signal is modulated. The modulated upstream optical signal enters the optical fiber 420 and is transmitted to the center station 4.
01 is transmitted. The optical signal is converted into an electric signal in the upstream optical-electrical conversion unit 670, and is frequency-converted into an upstream IF signal using the local oscillation signal output from the local oscillation signal source 690 in the upstream frequency conversion unit 680. .

As described above, the optical signal for uplink is multiplexed with the optical signal for downlink at the center station and transmitted, the optical signal for uplink is separated at the radio base station, and modulated by the radio signal received at the antenna section. By optical transmission again, the frequency conversion from the radio signal frequency to the IF signal frequency can be performed on the center station side, and the size of the radio base station can be reduced.

[0029]

As described above, according to the present invention, there is no need to electrically perform frequency conversion by optically performing frequency conversion using optical modulators connected in parallel.
Further, since unnecessary waves other than the desired RF signal component are hardly generated, a bandpass filter for removing unnecessary waves required for performing electrical frequency conversion becomes unnecessary, and the output from the photoelectric converter is reduced. It is possible to radiate directly from the antenna. Therefore, the size and cost of the wireless base station can be reduced.

Further, it is possible to set both the electric signal and the local oscillation signal in the intermediate frequency band to relatively high frequencies.
Since the frequency interval between the desired signal and the unnecessary wave becomes relatively wide after the frequency conversion, a bandpass filter for removing the unnecessary wave can be easily realized.

Also, the upstream optical signal is multiplexed with the downstream optical signal and transmitted, and the optical base station separates the optical signal and modulates the upstream optical signal with the wireless signal received by the antenna. Can be simplified, and a small wireless base station can be provided.

By sharing the local oscillation signal used for the frequency conversion in the downstream optical modulator and the frequency conversion in the frequency conversion unit connected to the upstream photoelectric conversion unit, only one local oscillation signal source is required.

[Brief description of the drawings]

FIG. 1 is a configuration diagram of an optical modulator according to a first embodiment of the present invention.

FIG. 2 is a diagram showing an example of an optical spectrum output from the optical modulator according to the first embodiment of the present invention.

FIG. 3 is a diagram showing another example of an optical spectrum output from the optical modulator according to the first embodiment of the present invention.

FIG. 4 is a configuration diagram of an optical wireless transmission system according to a second embodiment of the present invention.

FIG. 5 is a configuration diagram of an optical wireless transmission system according to a third embodiment of the present invention.

FIG. 6 is a configuration diagram of an optical wireless transmission system according to a fourth embodiment of the present invention.

FIG. 7 is a configuration diagram of a conventional wireless transmission system.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 IF input terminal 2 Local oscillation input terminal 11-16 1st-6th optical waveguide part 21-24 24st-4th electrode 31 optical input terminal 32 optical output terminal 100 optical modulation part 110 parallel optical modulation part 120- 1, 1st and 2nd branching unit 130-1 to 4th 1st to 4th driver unit 140-1 and 1st and 2nd light modulating unit 401 Center station 402 Wireless base station 410 Downlink light source 420 Optical fiber 430 Downlink photoelectric conversion unit 440 Downlink amplification unit 450 Antenna unit 510 Optical amplification unit 520 Antenna integrated photoelectric conversion unit 610 Uplink light source 620 Optical multiplexing unit 630 Optical separation unit 640 Circulator unit 650 Uplink amplification unit 660 Uplink Optical modulation unit 670 Up photoelectric conversion unit 680 Up frequency conversion unit 690 Local signal source 710 Intensity modulation unit 720 Down frequency conversion unit 30 filter unit

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Claims (8)

[Claims] 1. An optical modulator for inputting an optical signal, modulating and outputting the input optical signal, wherein the optical modulator receives an electric signal of an intermediate frequency band and outputs an electric signal of the intermediate frequency band. A first driver unit for applying a first bias voltage to a signal; a local oscillation signal used for frequency-converting the electric signal into a radio frequency band; and applying a second bias voltage to the local oscillation signal. A second driver unit, a two-branch unit that branches the input optical signal into two, and modulates one optical signal that is bifurcated by the two-branch unit with an electric signal output from the first driver unit. First
A second optical modulator that modulates the other optical signal that has been branched into two by the two-branch unit with an electric signal output from the second driver unit.
At least a first bias voltage applied by the first driver unit and a second bias voltage applied by the second driver unit.
Wherein the bias voltage is set such that the phases of the respective carrier components of the optical signals modulated by the first and second modulators are inverted. 2. The modulation performed in each of the first and second optical modulators is such that the frequency spectrum of the modulated optical signal has a carrier component and a one-sideband component, and
An SS that modulates such that the one-side band component of the optical signal modulated by the first optical modulator and the one-side band component of the optical signal modulated by the second optical modulator are positioned upside down.
2. The light modulation device according to claim 1, wherein the light modulation is B modulation. 3. A downlink light source; a downlink optical modulator for modulating light output from the downlink light source; an optical fiber transmitting an optical signal output from the downlink optical modulator; An optical-to-electrical converter for converting an optical signal output from a fiber into an electric signal, wherein the downstream optical modulator is the optical modulation device according to claim 1 or 2. . 4. The optical device according to claim 3, wherein the photoelectric converter further includes a planar antenna for emitting an electric signal obtained by converting the optical signal output from the optical fiber into a space as a wireless signal. Wireless transmission system. 5. A downstream light source for outputting a downstream optical signal; a downstream optical modulator for modulating light output from the downstream light source; an upstream light source for outputting an upstream optical signal; An optical multiplexing unit that multiplexes the downstream optical signal and the upstream optical signal modulated by the optical modulator, an optical fiber that transmits an optical signal output from the optical multiplexing unit, and an output from the optical fiber. An optical signal to be separated into the downstream optical signal and the upstream optical signal, and a downstream optical-electrical converter that converts the downstream optical signal output from the optical separator into an electric signal. A circulator section that sends an electric signal output from the downstream photoelectric conversion section to the antenna section, and outputs an electric signal output from the antenna section to the upstream optical modulator, and via the circulator section , The downstream photoelectric conversion unit Emitting the output electric signal to the space as a wireless signal, receiving the incoming wireless signal, and outputting the antenna unit to the circulator unit, by the electric signal output from the antenna unit via the circulator unit, An upstream optical modulator that modulates an upstream optical signal, an optical fiber that transmits the upstream optical signal, and an upstream optical-electrical converter that converts an upstream optical signal output from the optical fiber into an electric signal. An optical wireless transmission system, comprising: a local oscillation signal source that outputs the local oscillation signal; and the downstream optical modulator is the optical modulation device according to claim 1 or 2. 6. The optical wireless transmission system, comprising: a local oscillation signal branching unit that branches a local oscillation signal output from the local oscillation signal source into two; and an electrical signal output from the upstream optical-electrical conversion unit. A frequency conversion unit that receives one of the local oscillation signals output from the local oscillation signal branching unit and converts the local oscillation signal into an electric signal in an intermediate frequency band; and the other station that is output from the local oscillation signal branching unit. 6. The down-converted optical modulator inputs a generated signal.
An optical wireless transmission system according to claim 1. 7. An optical modulation method for inputting an optical signal, modulating the input optical signal, and outputting the input optical signal, the optical modulation method comprising: inputting an electric signal in an intermediate frequency band; A first driver step of applying a first bias voltage to a signal; inputting a local oscillation signal used for frequency-converting the electric signal to a radio frequency band; and applying a second bias voltage to the local oscillation signal A second driver step of performing the following: a two-branch step of branching the input optical signal into two; and modulating one of the two optical signals in the two-branch step with an electric signal output from the first driver step. A second optical modulation step of modulating the other optical signal that has been branched into two in the two-branch step with an electric signal output from the second driver step At least the first bias voltage applied in the first driver step and the second bias voltage applied in the second driver section are equal to the first and second optical modulations. An optical modulation method characterized in that the phases of the respective carrier components of the optical signals modulated in the steps (1) and (2) are set to be inverted. 8. The modulation performed in each of the first and second optical modulation steps is such that the frequency spectrum of the modulated optical signal has a carrier component and a one-sideband component.
In addition, the modulation is performed so that the one-sideband component of the optical signal modulated in the first optical modulation step and the one-sideband component of the optical signal modulated in the second optical modulation step are positioned upside down. The light modulation method according to claim 7, wherein the light modulation method is SSB modulation.